KR20080075892A - Method and system for automatically determining boundary threshold between systems - Google Patents

Abstract

A method and system for determining thresholds for evaluating inter-system handovers in a wireless communication system includes determining a quality level of a first digital duplexing type (104), determining a quality level of a second digital duplexing type (106), and comparing the quality levels to determine whether to handover from the first digital duplexing type (104) to the second duplexing type (106).

Description

METHOD AND SYSTEM FOR AUTOMATED DETERMINATION OF INTER-SYSTEM BORDER THRESHOLDS}

The present invention relates to a wireless communication network having a system in which coverage areas overlap. More specifically, the present invention relates to handover between systems in a wireless communication network.

Referring to FIG. 1, a time division duplex overlapping with a Universal Mobile Telecommunications System (UMTS) using a frequency division duplex 12 (hereinafter referred to as “FDD system”). A general purpose mobile communication system using Duplex 10 (hereinafter " TDD system ") is shown. FIG. 2 shows the reverse case, showing an FDD system 12 that overlaps with a wide area TDD system 10. A handover may be possible between the two systems 10, 12, but to do so, a measurement is performed by a wireless transmit and receive unit (WTRU) so that the measured value determines the handover. Radio Network Controller).

Event 2b, which may be used when performing inter-system handover (ie, handover between TDD system 10 and FDD system 12), was announced in December 2002 as "3GPP TS 25.331 V4.8.0 Third Generation Partnership Project". Technical Specification Group Radio Access Network (RFC); Radio Resource Control (RRC); Protocol Standard (Release 4) "(hereinafter" Standard "). Event 2b is defined in the standard as being an event in which "the estimated quality of a frequency is below a predetermined threshold and the estimated quality of an unused frequency is above a predetermined threshold" that is currently used. It is important that the unused frequency is always the frequency of the system to which the WTRU is handed over. Therefore, there are two thresholds for evaluating intersystem handover (i.e. handover between TDD and FDD systems) using event 2b, (1) minimum quality requirements of TDD system 10, and (2) FDD system 12. Minimum quality requirements are required.

The minimum quality condition of the TDD system 10 is based on the received signal code power (RSCP) of the primary common control physical channel (P-CCPCH) (hereinafter collectively referred to as "P-CCPCH RSCP"). The minimum quality requirements of the FDD system 12 are RSCP of the common pilot channel (CPICH) (hereinafter collectively referred to as "CPICH RSCP") and signal-to-noise ratio (Ec / No) of the common pilot channel (CPICH) (hereinafter collectively " CPICH Ec / No ").

These minimum quality values are highly dependent on the particular placement (eg, Manhattan microcell placement) and can be set manually for each cell in the TDD / FDD boundary region. The interference pattern is different if the arrangement is different. For example, the standard deviation of lognormal fading is different for different batches, and the standard deviation is usually higher for a microcell than the area shown. Multipath interference also differs if the arrangement is different. This means that if the quality level of the beacon of -105dBm is sufficient to support communication of one cell with low interference, the interference may be higher and may not be enough to support communication of other cells. For ease of management, it is desirable to provide an automated method and system for determining the thresholds required to evaluate inter-system handover.

The present invention is a method and system for automatically determining an intersystem boundary threshold. Automated threshold determination is used to make handover decisions between TDD and FDD systems.

A first preferred method of the present invention for determining a threshold for evaluating inter-system handover in a wireless communication system includes determining a quality level of a first digital duplexing type and a quality level of a second digital duplexing type. And comparing the quality level to determine whether to handover from the first digital duplexing type to a second digital duplexing type.

Another preferred method of the present invention includes determining a first minimum quality level for a first duplexing type and a second minimum quality level for a second duplexing type. Next, the first minimum quality level is compared with the first threshold and the second minimum quality level is compared with the second threshold. Finally, the handover from the first duplexing type to the second duplexing type is initiated when the first minimum quality level is below the first threshold and the second minimum quality level is above the second threshold.

A system constructed in accordance with the present invention for determining a threshold for evaluating inter-system handover between a first duplexing type and a second duplexing type in a wireless communication system operates in both a first duplexing type and a second duplexing type. It includes a plurality of possible multi-mode WTRUs. The system also includes setting means for setting a minimum quality level for the first duplexing type, indicating means for instructing each WTRU to inform the coverage range of the second duplexing type, and the WTRU in the first duplexing type. RNC with determining means for determining whether to hand over to a second duplexing type. Finally, the system includes at least one base station connecting between the plurality of WTRUs and the RNC.

According to a system and method for automatically determining an intersystem boundary threshold, an automated threshold determination is used to perform handover decisions between TDD and FDD systems.

Referring back to FIG. 1 and referring first to handover from the TDD system 10 to the FDD system 12 (ie, TDD-FDD handover), the handover not only occurs at the TDD-FDD boundary, but also internally. It also occurs internally in the TDD-TDD system 10 on the TDD-TDD boundary. These handovers are triggered based on the relative P-CCPCH RSCP level of the TDD cell. The P-CCPCH RSCP level at which handover from one TDD cell to another TDD cell occurs depends on the cell plan and will indicate a limitation of cell coverage.

The minimum quality level of the TDD system 10 (ie, the threshold used to evaluate the estimated quality of the frequency currently used) may be referred to as the TDD minimum quality level or TDD threshold. This threshold can be deduced from the P-CCPCH RSCP level used for internal TDD-TDD handover. That is, the TDD threshold value used for handover on the TDD-FDD boundary may be, for example, an average value of P-CCPCH RSCP that was used as a threshold for evaluating TDD-TDD handover in the TDD system 10. The TDD threshold is not necessarily an average value, but may be a percentile, such as the 95th percentile.

The range of FDD coverage 12 that overlaps / contacts the TDD cell may be determined by having the RNC report the level of FDD coverage to the multi-mode (ie, TDD and FDD) WTRUs. Again, event 2c, which is part of the aforementioned standard, can be used to define the range of FDD coverage as "the estimated quality of the unused frequency is above a certain threshold". As mentioned above, in this scenario, the unused frequency is an FDD frequency. This FDD threshold may thus be derived based on the information reported by the multi-mode WTRU.

There are other cases where it may be desirable to set a handover threshold that is different from the reporting threshold. The reporting threshold represents the minimum quality that can maintain communication. The estimated quality may be higher than this. For example, the reporting threshold may be -105 dBm and the estimated quality may be -80 dBm. Derivation of the handover threshold is based on desired system performance and also based on the load of the TDD system. This case is as follows.

(1) Handover to FDD is preferred if the FDD signal quality is low. The reason is because of the preference for FDD service or high load in TDD system. In this case, the handover threshold would be set to the reporting threshold (eg -1.5 dBm) if the value was reported.

(2) Handover to FDD is preferable only in the region where the estimated quality is reported to be high. In this case, the handover threshold would be set to a higher value if the value was reported (eg -85 dBm).

In order to obtain a signal about an unused frequency, the WTRU is informed of the additional frequency to measure using the RNC. The WTRU does not use these frequencies for communication but it is possible to measure them. In the case of TDD, unused frequencies are measured during timeslots that are not used for communication. In the case of FDD, the unused frequency is measured in compression mode.

Referring now to FIG. 2, in a handover from an FDD system 12 to a TDD system 10 (ie, FDD-TDD handover), the handover not only occurs at the FDD-TDD boundary, but also the FDD-FDD cell. It also occurs internally in the FDD system 12 on the boundary. These handovers are triggered based on the relative quality level (CPICH RSCP or CPICH Ec / No) of the FDD cell. The level at which the handover from one FDD cell to another FDD cell occurs depends on cell plan and will indicate a limit of cell coverage.

The minimum quality level of the FDD system 12 (threshold value used to evaluate the estimated quality of the frequency currently used) may be referred to as the FDD minimum quality level or FDD threshold value. This threshold can be inferred from a particular internal quality level chosen to evaluate FDD-FDD handover. That is, the FDD threshold used for handover on the FDD-TDD boundary may be, for example, the average internal quality level that was used as the threshold for evaluating FDD-FDD handover of the FDD system 12. The FDD threshold is not necessarily average, but may be a percentile, such as the 95th percentile.

The range of TDD coverage 10 that overlaps / contacts with the FDD cell may be determined by having the multi-mode WTRU report the level of TDD coverage to the RNC. Event 2c may be used here to define the range of TDD coverage as the estimated quality of the unused frequency, in this case the TDD frequency, is above a predetermined threshold. As such, the TDD threshold may be derived based on information provided by the multi-mode WTRU. Deriving the TDD threshold may be performed in the same manner as deriving the FDD threshold, as described above. Note that there is no room for bandwidth availability on FDD or TDD. However, the handover threshold may be set because of the load in the system as described above.

Referring now to FIG. 3, shown is a flow diagram of a method 50 for determining the threshold required to evaluate TDD-FDD and FDD-TDD handover. The method 50 begins at step 52 and proceeds to step 54 to determine the type of system in which the WTRU currently being evaluated for handover is currently operating. For convenience of description, two types are shown (ie, TDD and FDD), but the method 50 may be implemented for any number of and / or types of systems that may be used in combination with a wireless communication network. It should be noted that.

If the WRTU is currently operating in the TDD system, the method 50 proceeds to step 56. In steps 56 to 64, a threshold for evaluating TDD-FDD handover is determined. First, in step 56, the minimum TDD quality level is set based on the P-CCPCH RSCP used for internal TDD-TDD handover. The minimum TDD quality level may be an average value or percentile (eg, 95th percentile), for example, depending on the operator's preference. Once the minimum TDD quality level has been set, the method 50 proceeds to step 58. In step 58, event 2c is set for all multi-mode WTRUs to report the range of FDD coverage within the TDD system. In step 60, the minimum FDD quality level is set based on the FDD reporting from the multimode WTRU. In step 62, reporting of event 2c is disabled. In step 64, the WTRU is informed of the minimum TDD and FDD quality levels that may be used in event 2b to assess whether TDD-FDD handover may occur.

If the WTRU is currently operating in an FDD system, the method 50 proceeds from step 54 to step 66. In steps 66 to 74, a threshold for evaluating FDD-TDD handover is determined. First, in step 66, the minimum FDD quality level is set. The minimum FDD quality level may be based on CPICH RSCP or CPICH Ec / No as is being used to evaluate the internal FDD-FDD handover. The minimum FDD quality level may be, for example, an average value or a percentile (eg, 95th percentile), depending on operator preference. Once the minimum FDD quality level is set, the method 50 proceeds to step 68. In step 68, event 2c is set for all multi-mode WTRUs to report the range of TDD coverage in the FDD system. In step 70, the minimum TDD quality level is set based on the TDD reporting from the multimode WTRU. In step 72, the report of event 2c is displayed. In step 74, the WTRU is informed of the TDD and FDD quality levels that may be used in event 2b to evaluate whether FDD-TDD handover may occur.

Once the appropriate quality level is provided (ie, from step 64 or step 74), the method ends at step 76. The method 50 may be performed if desired whenever a quality level is needed to evaluate intersystem handover.

Referring now to FIG. 4, a diagram of a system 100 is provided that provides a threshold for evaluating intersystem handover. For purposes of describing the system 100, a TDD system 106 is shown that overlaps with the wide area FDD 104. The system includes at least one radio network controller (RNC) 102, a plurality of base stations 108, and a plurality of multi-mode WTRUs (ie, user equipment) 109.

To further illustrate the system 100, a multi-mode WTRU 110 is shown that is a candidate for handover from TDD to FDD (ie, TDD-FDD handover). In this example, it is assumed that WTRU 110 is operating in a TDD system but is being evaluated for handover to the FDD system. To evaluate the handover, the RNC 102 sets a minimum TDD quality level based on the P-CCPCH-RSCP used for internal TDD-TDD handover. The RNC 102 will also instruct the multi-mode WTRUs 109, 110 mode to report the range of FDD coverage. The threshold used to determine the range of FDD coverage is used as the minimum FDD quality level. If the RNC 102 has all of the required quality levels, those levels are sent to the WTRU 110. The WTRU 110 uses this quality level to determine the satisfaction of event 2b. If event 2b is satisfactory, the WTRU 110 will be handed over from TDD to FDD, otherwise the WTRU 110 will remain in TDD mode.

Although the present invention has been described in detail, the present invention is not limited to the described, and various changes can be made within the scope of the present invention as defined in the appended claims.

1 is a diagram illustrating a UMTS-TDD system overlapping with a wide area FDD system.

2 is a diagram illustrating a UMTS-FDD system overlapping with a wide area TDD system.

3 is a flowchart of a method of determining a threshold required to evaluate handover between a TDD and FDD system.

4 is a diagram of a system in which a threshold used to evaluate handover between a TDD and FDD system is automatically determined.

Claims (21)

A method of operating a multi-mode wireless transmit / receive unit (WTRU), Receiving signals from both time division duplex (TDD) and frequency division duplex (FDD) systems; Establishing a connection with one of the systems; Measuring a quality of a signal received from both the TDD system and the FDD system; Comparing the measured signal quality of the TDD system with a TDD threshold and comparing the measured signal quality of the FDD system with an FDD threshold; And Handover from the system in which the connection is established to the other system if the measured signal quality of the current system is below the threshold of the current system and the measured signal quality of the other system exceeds the threshold of the other system. A method of operating a multi-mode wireless transmit / receive unit (WTRU) comprising a. 2. The method of claim 1 wherein the TDD threshold is determined based on received signal code power of a primary common control physical channel. 3. The method of claim 1 or 2, wherein the FDD threshold is determined based on the received signal code power of a common pilot channel. 3. The method of claim 1, wherein the FDD threshold is determined based on a signal-to-noise ratio of a common pilot channel. 4. A multi-mode wireless transmit / receive unit (WTRU), A transceiver configured to establish a connection with both time division duplex (TDD) and frequency division duplex (FDD) systems and receive signals from both the time division duplex (TDD) and frequency division duplex (FDD) systems; Means for measuring a quality of a signal received from both the TDD system and the FDD system; Means for comparing a measured signal quality of the TDD system with a TDD threshold and comparing the measured signal quality of the FDD system with an FDD threshold; And If the measured signal quality of one of the systems is below the threshold of the system, and if the measured signal quality of another of the systems exceeds the threshold of the other system, the WTRU is one of the systems. Means for handover between a TDD system and an FDD system configured to switch from a connection through a connection to another system Multi-mode wireless transmit and receive unit (WTRU) comprising. 6. The WTRU of claim 5 further comprising means for determining the TDD threshold based on received signal code power of a primary common control physical channel. 7. The WTRU of claim 5 or 6 further comprising means for determining the FDD threshold based on received signal code power of a common pilot channel. 7. The WTRU of claim 5 or 6 further comprising means for determining the FDD threshold based on a signal-to-noise ratio of a common pilot channel. A method of determining a threshold for evaluating intersystem handover, Determining an estimated minimum quality level of the first digital duplexing type based on a threshold for intersystem handover of the first digital duplexing type. Setting a first handover threshold to the evaluated minimum quality level of a first digital duplexing type; Determining an actual quality level for the second digital duplexing type based on information about the coverage of the second digital duplexing type from a plurality of multi-mode wireless transmit / receive units (WTRUs) included in the wireless communication system. Determining an actual quality level for the second digital duplexing type, wherein the actual quality level represents a minimum quality required to continue communication in the second digital duplexing type; Setting a reporting threshold to the actual quality level of the second digital duplexing type; Determining whether an estimated minimum quality level of the second digital duplex type is greater than an actual quality level of the second digital duplexing type based on a threshold for intersystem handover of the second digital duplexing type. ; If the determination is affirmative, setting a second handover threshold to the reporting threshold; And If the determination is negative, setting the second handover threshold to the evaluated minimum quality level of the second digital duplexing type. Threshold determination method comprising a. 10. The method of claim 9, wherein the estimated minimum quality level of the first digital duplexing type is determined by a WTRU using a primary channel signal level. The threshold determination method of claim 10, wherein the estimated minimum quality level of the second digital duplexing type is determined by a WTRU using a secondary channel signal level derived from an estimated quality of unused frequencies. Way. 10. The method of claim 9, wherein the first digital duplexing type is a time division duplex and the second digital duplexing type is a frequency division duplex. 10. The method of claim 9, wherein the first digital duplexing type is frequency division duplex and the second digital duplexing type is time division duplex. 10. The method of claim 9, wherein the quality level of the first digital duplexing type is based on the received signal code power of the primary common control physical channel. 10. The method of claim 9, wherein the first threshold is an average value of estimated minimum quality level values of the first digital duplexing type, and the second threshold is an average value of evaluated minimum quality level values of the second digital duplexing type. Threshold determination method. 10. The method of claim 9 wherein the first threshold and the second threshold are percentile values. 10. The method of claim 9, wherein the first digital duplexing type is a time division duplex and the second digital duplexing type is a frequency division duplex. 10. The method of claim 9, wherein the first duplexing type is frequency division duplex and the second duplexing type is time division duplex. 10. The method of claim 9, wherein determining the estimated minimum quality level value comprises calculating the received signal code power of the primary common control physical channel. 10. The method of claim 9, wherein determining the estimated minimum quality level value comprises calculating a received signal code power of a common pilot channel. 10. The method of claim 9, wherein determining the estimated minimum quality level value comprises calculating a signal to noise ratio of a common pilot channel.

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